Hvac systems and methods with refrigerant leak detection

ABSTRACT

Systems and methods are disclosed that involve detecting a flammable refrigerant associated with a heating, ventilating, and air conditioning (HVAC) system. In one instance a damper covers an access port allowing a single sensor to monitor at least two separate spaces. In another instance, a multi-probe sensor allows a single sensor to monitor at least two separate spaces. Other systems and methods are presented.

FIELD

This application is directed, in general, to heating, ventilating andair conditioning or cooling (HVAC) systems, and more specifically, tomethods and systems with economical refrigerant leak detection.

BACKGROUND

Heating, ventilating, and air conditioning (HVAC) systems can be used toregulate the environment within an enclosed space. Typically, an airblower is used to pull air (i.e., return air) from the enclosed spaceinto the HVAC system through ducts and push the air into the enclosedspace through additional ducts after conditioning the air (e.g.,heating, cooling or dehumidifying the air). Unless otherwise indicated,as used throughout this document, “or” does not require mutualexclusivity. Various types of HVAC systems may be used to provideconditioned air for enclosed spaces.

The cooling aspect of the HVAC system utilizes a working fluid, orrefrigerant, that cycles through various phases to realize cooling at adesired location. In the past, refrigerants were selected that were inlarge measure non-toxic and non-flammable. These refrigerants were not,however, as desirable with respect to global warming potential. In morerecent times, a push has been made to use refrigerants that have a lowor lower global warming potential. Because such refrigerants are oftenat least mildly flammable, the refrigerant could pose a potential riskto the user in some situations.

BRIEF DESCRIPTION

Illustrative embodiments of the present invention are described indetail below with reference to the attached drawing figures, which areincorporated by reference herein and wherein:

FIG. 1 is a schematic elevation view diagram of an HVAC system accordingto an illustrative embodiment;

FIG. 2 is a schematic plan view diagram of portion of an HVAC having aleak detector according to an illustrative embodiment;

FIG. 3 is an illustrative flow chart of an aspect of a method ofdetecting a refrigerant leak according to an illustrative embodiment;

FIG. 4 is a schematic plan view diagram of portion of an HVAC having aleak detector according to an illustrative embodiment;

FIG. 5 is a schematic diagram of portion of an HVAC having a leakdetector according to an illustrative embodiment; and

FIG. 6 is an illustrative flow chart of an aspect of a method ofdetecting a refrigerant leak according to an illustrative embodiment.

DETAILED DESCRIPTION

In the following detailed description of the preferred embodiments,reference is made to the accompanying drawings that form a part hereof,and in which is shown, by way of illustration, specific embodiments inwhich the invention may be practiced. These embodiments are described insufficient detail to enable those skilled in the art to practice theinvention, and it is understood that other embodiments may be utilizedand that logical structural, mechanical, electrical, and chemicalchanges may be made without departing from the spirit or scope of theinvention. To avoid detail not necessary to enable those skilled in theart to practice the invention, the description may omit certaininformation known to those skilled in the art. The following detaileddescription is, therefore, not to be taken in a limiting sense, and thescope of the present invention is defined only by the claims.

Referring now to the drawings and primarily to FIG. 1, a heating,ventilating, and air conditioning (HVAC) system 100 is presented. TheHVAC system 100 is for providing conditioned air to a first closed space102, such as the interior of a building. At least a portion of the HVACsystem 100 is disposed within a second closed space 104, or equipmentspace. The spaces may be defined by a plurality of walls 105. In thisembodiment, a portion 106 of the system 100 is located within thebuilding, i.e., within the second closed space 104, and a portion 108outside the building.

The HVAC system 100 includes an HVAC unit 110 that is disposed withinthe second closed space 104, or equipment space. The HVAC unit 110includes a return air duct 112 that receives air 115 from the firstclosed space 102. The return air duct 112 may include or be coupled to atransition duct 114 that may include one or more filters 116. A blower118 pulls the return air into the return air duct 112. The blower 118 isfluidly coupled to the return air duct 112. The blower 118 moves airinto a conditioning compartment 120.

The conditioning compartment 120 is fluidly coupled to the blower 118for receiving air therefrom to be treated. The conditioning compartment120 is formed with a plurality of compartment walls and formed with asampling port 122 on one compartment wall. The conditioning compartment120 may include a portion of a delivery duct 132 in some embodiments.The sampling port 122 is selectively covered by a damper 124 (FIG. 2).The damper 124 is includes activation devices, e.g., motor or solenoidor other motive device, whereby a damper-control signal may be sent tothe damper 124 to open or close the damper 124.

The conditioning compartment 120 includes a heating device 126 and acooling unit 128. The order of the heating device 126 and cooling unit128 could be varied. The heating device 126 may be a furnace, hot watermanifold, an electric heating element, or any source of heat. If theheating device 126 is a furnace it may include flue pipe 127. Theheating device 126 is fluidly coupled to the conditioning compartment120 for selectively heating air therein. The cooling unit 128 is fluidlycoupled to the conditioning compartment 120 for selectively cooling airtherein. The cooling unit 128 includes a flammable refrigerant, orworking fluid. The cooling unit 128 may be an evaporator coil or devicefor receiving heat from the air flowing over the cooling unit. Thecooling unit 128 includes at least one heat exchange surface.

While the system 100 will work with many refrigerants, the system 100 isprimarily concerned with flammable refrigerants. Flammable refrigerantsinclude even mildly flammable refrigerants that if exposed to anignition source under certain conditions could pose a risk of fire.Accordingly, leak detection is an issue of considerable interest andwill be described further below. The flammable refrigerant may be,without limitation, any of the following: any A2L, A2, A3, B2, or B3refrigerant; R1234YF by Honeywell and DuPont; methylene chloride (R30);methyl chloride (R40); ethane (R170); propane (R290); N-Butane (R600);isobutene (R-600A); methyl formate (R611); ammonia (R717); sulfurdioxide (R764); ethylene (R1150); hydrocarbon refrigerants;halo-hydrocarbon blends; difluoromethane (R-32); etc.

Whether heated by heating device 128 or cooled by cooling unit 128, theconditioning compartment 120 produces a treated air 130 that isdelivered into the first closed space 102 by the delivery duct 132. Thedelivery duct 132 is fluidly coupled to the conditioning compartment 120for discharging the treated air 130 from the conditioning compartment120 into the first closed space 102.

Referring additionally to FIG. 2, the processing unit 134 is associatedwith the HVAC unit 110. The processing unit 134 includes one or moreprocessors 136 and one or more memories 138. The processing unit 134 mayinclude an input 140 (e.g., touchpad, keyboard, etc.) and an output 142(e.g., display). The processing unit 134 may be communicatively coupled(in communication through wires, wireless, or other means) with theblower 118, damper 124, or other devices to be monitored or controlledwithin the system 100.

The one or more processors 136 are configured to execute one or moresequences of instructions, programming or code stored on or in the oneor more memories 138, which includes all types of memory devices andincludes readable medium used for storage. The processor 136 can be, forexample, a general purpose microprocessor, a microcontroller, a digitalsignal processor, an application specific integrated circuit, a fieldprogrammable gate array, a programmable logic device, a controller, astate machine, a gated logic, discrete hardware components, anartificial neural network or any like suitable entity that can performcalculations or other manipulations of data. The memory 138 may includeone or more the following: random access memory (RAM), flash memory,read only memory (ROM), programmable read only memory (PROM), erasablePROM, registers, hard disks, removable disks, CD-ROMS, DVDs, or anyother suitable storage devices.

The cooling unit 128 is associated with a cooling subsystem 144. Thecooling subsystem 144 is any system that is operational to develop achilled working fluid for receiving heat within the cooling unit 128. Inone embodiment, the cooling subsystem 144 includes a closed-conduitpathway 145, or circuit. The flammable refrigerant is disposed withinthe closed conduit pathway 145. The closed-conduit pathway 145 includesa first refrigerant line 146 and a second refrigerant line 148. It willbe appreciated that the first and second refrigerant lines 146, 148 inthis embodiment are disposed partially within the second closed space104 and if they were to leak, could deliver the flammable refrigerantinto the second closed space 104 and thereby pose a potential safetyrisk—particularly if a source of ignition is present. Similarly if therefrigerant leaks within the cooling unit 128 and therefore within theconditioning compartment 120, a risk may be posed by potential ignitionsources, e.g., an open flame from a furnace. Additional spaces may needdetectors, particularly if a refrigerant line in the space has a joint.

The cooling subsystem 144 also includes a compressor 150 fluidly coupledto the closed-conduit pathway 145 for compressing the flammablerefrigerant therein. A condenser 152 is fluidly coupled to theclosed-conduit pathway 145 downstream of the compressor 150 for coolingthe refrigerant. The condenser 152 may include on or more fans 154. Anexpansion device 156 is coupled to the closed-conduit pathway 145downstream of the condenser 152 for decreasing a pressure of therefrigerant at the cooling unit 128. The cooling unit 128 includes aheat-exchange surface (not explicitly shown) and is fluidly coupled tothe closed-conduit pathway 145 for receiving the flammable refrigerant.

A control unit 158 may be disposed within the first closed space 102.The control unit 158 may include a thermostat for providing controlsignals to the blower 118, heating device 126, or cooling unit 128 (orcooling subsystem) in response to a temperature in the first closedspace 102. The control unit 158 may include an input device and adisplay, such as a touch-screen display 160 and a speaker 162 foraudible alerts or instructions. The control unit 158 is communicativelycoupled, e.g., by wireless signal 164 or wired signal, to the processingunit 134. In some embodiments, the control unit 158 and the processingunit 134 may be the same unit.

A flammable-component detector 166 is disposed within the second closedspace 104 and positioned proximate the HVAC unit 110 such that anyflammable refrigerant within the conditioned compartment 120 would flowthrough the sampling port 122 when the damper 124 (FIG. 2) is open andonto the flammable-component detector 166. The flammable-componentdetector 166 is operable to produce a detection signal indicative of thelevel of the flammable component detected or a signal that a lowerthreshold has been reached.

Referring now primarily to FIG. 2, a portion of an HVAC system 100 ispresented that is analogous most respects to that of FIG. 1. The HVACunit 110 is shown disposed within the second closed space 104. In thisfigure, the damper 124 covering sampling port 122 is shown. The damper124 is communicatively coupled to a processing unit 134, such as a by awireless connection or by wires 168. The processing unit 134 iscommunicatively coupled to the damper 124 for selectively providing adamper-control signal thereto to open and close the damper 124. Thedamper 124 includes an activation device to open or close the damperover the sampling port 122. Located proximate to the sampling port 122and damper 124 and preferably at a lower elevation is aflammable-component detector 166. The flammable-component detector 166is communicatively coupled to the processing unit 134 by a wirelessconnection or by a wired connection 165 or other means.

The processing unit 134 may be further communicatively coupled to theblower 118 to receive an operational-status signal from the blower 118.In some embodiments, the processing unit 134 is able to monitoroperation of the blower 118 and provide control signals thereto toeffect the operation of the blower 118.

The flammable-component detector 166 is positioned so that if there is aleak of the flammable refrigerant within the conditioning compartment120, when the sampling port 120 is in an open position, the refrigerantwill pour from the sampling port 120 onto the flammable-componentdetector 166. In this way, the flammable-component detector 166 is ableto monitor and detect a leak of refrigerant within the conditioningcompartment 120 when the damper 124 is open and also monitor the secondclosed space 104 where the flammable-component detector 166 ispositioned. It should be noted that when the blower (see 118 in FIG. 1)is operative, any refrigerant leak is diluted and therefore should poseno risk. When the blower is off, the damper 124 may be opened andpotential leaks monitored.

If the detection signal from the flammable-component detector 166 thatis delivered to the processing unit 134 exceeds an alert threshold,responsive action is taken. The response may include sending an alertsignal to the control unit 158. The alert signal may be presented as avisual alert on the screen 160, an audible alert through speaker 162(FIG. 1), or other alert. This allows an active warning to the user inthe first closed space 102 of the potential danger posed elsewhere,namely in the conditioning compartment 120 or second closed space 104.

The responsive action may include closing the damper 124 and activatingthe blower 118 (FIG. 1) or may include activating a ventilator 170. Theventilator 170 may be a fan that pulls air out of the second closedspace 104 or moves air into the second closed space 104 for the purposeof diluting any leaked refrigerant. The ventilator 170 iscommunicatively coupled to the processing unit 134, e.g., by wireless orwired 172 connection or other means.

In one illustrative embodiment, the at least one processor 136 and atleast one memory 138 are configured to perform the following steps:receive the operational-status signal from the blower 118; open thedamper 124 when the operational-status signal from the blower indicatesthat the blower 118 is not operating; and close the damper 124 when theoperational-status signal from the blower 118 indicates that the blower118 is operating. The at least one processor 136 and at least one memory138 may be further configured to monitor the detection signal from theflammable-component detector 166 and to send an alert when the detectionsignal is indicative a flammable component at least equal to an alertthreshold. The alert may be an alert signal sent to the control unit 158(FIG. 1) present a visual or audible alert for the user in the firstclosed space 102. The user may have to select something to clear thealert. The processing unit 134 may prepare a blower-control signal toactive the blower in response a detection signal indicative of aflammable component at or near an alert threshold. In anotherembodiment, the processing unit 134 also prepares aventilation-activation signal that is sent to the ventilation blower 170to assist with diluting any leaked refrigerant in the second closedspace 104, or equipment space.

It will be appreciated that the processing unit 134 may be configured tocarryout numerous steps or functions within the system 100. As oneexample, reference is now made primarily to FIG. 3. In an illustrativeprocess 200 in FIG. 3, the process 200 first considers whether theblower is on at interrogatory 202. If it is on, any refrigerant leakwithin the conditioning compartment 120 would be diluted and so thedamper 124 is closed at step 204 to prevent air from entering theconditioning compartment 120. If the blower is not on, a leak could bean issue, and so the damper 124 is opened at step 206. In this way, theflammable-component detector 166 is effectively monitoring both thesecond closed space 104 and the conditioning compartment 120. If theflammable-component detector 166 detects a level of one or moreflammable components that exceeds an alert threshold, responsive actionis taken. This question is considered at interrogatory 208. If the alertthreshold is exceeded, responsive action is taken at step 210. Theresponse may include sounding an audible alarm, presenting a visualalert, sending an email to the user or service provide or emergencypersonnel, activating the blower 118, activating a ventilator 170, etc.If the flammable-component detector 166 does not detect one or moreflammable components exceeding an alert threshold, normal operationcontinues as shown as step 212 and the process returns to 202.

The alert threshold may be set at a conservative percentage of a lowerflammability limit. For example, the alert threshold may be set at 25%of the lower flammability limit for the flammable refrigerant beingused. Other safety margins—greater or lesser than 25%—may be used. Forexample, without limitation, the alert threshold may be 10, 20, 30, 40,or 50% of the lower flammability limit.

Referring now primarily to FIG. 4, a portion of an HVAC system 100 isshown. The HVAC system 100 of FIG. 4 is analogous in most respects tothe HVAC system of FIG. 1, and accordingly, some parts are labeled butnot further described here. In addition, components referenced but notexplicitly shown are analogous to those previously presented. In thisembodiment, however, there is no sample port, but rather aflammable-component detector 166 has a first probe 174 and a secondprobe 176 fluidly coupled to the detector 166. The first probe 174 isfluidly coupled to the flammable-component detector 166 and to theconditioning compartment 120. The second probe 176 is fluidly coupled tothe flammable-component detector 166 and to the second closed space 104.This illustrative embodiment also includes a selector 178 forselectively providing fluid flow through the first probe 174 and forselectively providing fluid flow through the second probe 176 to theflammable-component detector 166. The selector 178 may be a plurality ofvalves, a plurality of sample blowers, or other devices.

Referring now additionally to FIG. 5, the first probe 174 and secondprobe 176 are shown in more detail with associated components in oneillustrative embodiment. For illustration purposes, a plurality ofvalves 180 is shown. In addition a sample blower 182 is shown that pullsfluid 184 through either open probe 174, 176 across theflammable-component detector 166. The plurality of valves 180 iscontrolled by the processing unit 134 and is shown communicativelycoupled by wires 185 but of course it could be coupled by wireless or byother communication techniques. Similarly, the sample blower 182 may becontrolled by the processing unit 134 and is shown coupled by wire 186but of course it could be coupled by wireless or by other communicationtechniques.

In some embodiments, only valves are needed because of theflammable-component detector 166 is positioned at a location where anyleaking refrigerant will run through the probe to theflammable-component detector 166. In some embodiments, a sample blower182 may be added to pull sample fluid past the flammable-componentdetector 166 and be used with valves 178, 180 or may be blowersindividually associated with the probes 174, 176 and individuallyactivated. The flammable-component detector 166 may, for example, beused for ten seconds with the first probe 174 and then for ten secondwith the second probe 176 and so forth. Other time intervals may beused. This approach allows one flammable-component detector 166 tomonitor two spaces. It will be appreciated that this approach may beextended to a third space with a third probe and so on.

With respect to the monitoring of the flammable-component detector 166by the processing unit, it will be appreciated that the fluid deliveredby each probe 174, 176 may be diluted by the fluid in the other, andaccordingly the alert threshold may be set to account for the dilution.This is shown in an the illustrative process flow of FIG. 6.

It will be appreciated that the processing unit 134 of FIGS. 4-5 may beconfigured to carryout numerous steps or functions within the system100. As one example, reference is now made primarily to FIG. 6. Theprocess 300 begins at 302 and at 304 the number of probes (P) isentered. For example, if the system of FIG. 5 were involved, two wouldbe entered. If the number of probes were one, the process proceeds frominterrogatory 306 to step 308, which sets the alert threshold at anormal limit (N), e.g., 25% lower flammability limit. If the answer tointerrogatory 306 is negative, interrogatory 310, which asks if thereare two probes, is considered. If there are two probes, at step 312, thealert threshold is set to ½ of normal limit (N), or base limit, e.g.,12.5% of the lower flammability limit (if the normal limit is 25% of thelower flammability limit).

If the answer to interrogatory 310 is negative, interrogatory 314, whichasks if there are three probes, is reached. If affirmative, at step 316the alert threshold is set to ⅓ of normal limit (N), e.g., 8.3% lowerflammability limit (if the normal limit is 25% of the lower flammabilitylimit). This approach could continue as suggested by 318 to accommodateother numbers of probes.

In one embodiment, the processing unit 134 considers samples from bothprobes 174, 176 and compares the results against each other. In thisway, errors from calibration or drift may be cancelled out. If thedifference between the two is greater than a difference threshold, analert is triggered.

According to an illustrative embodiment, an HVAC system for providingconditioned air to a first closed space is provided, wherein at least aportion of the system is disposed within a second closed space, includesa cooling unit including a flammable refrigerant and at least onecompartment wall separating the cooling unit from an equipment space.The at least one compartment wall is formed with an access porttherethrough. The system further includes a controllable damperassociated with the access port for selectively covering the access portand a flammable-component detector disposed within the equipment spaceproximate the access port, which is through the at least one compartmentwall. The system also includes a processing unit communicatively coupledto the damper for opening and closing the damper.

Unless otherwise specified, any use of any form of the terms “connect,”“engage,” “couple,” “attach,” or any other term describing aninteraction between elements is not meant to limit the interaction todirect interaction between the elements and may also include indirectinteraction between the elements described. Coupling includes in someinstances communicatively coupled, which may be a wireless connection ora wired connection. Coupled in some instances may refer to fluidcoupling. In the discussion herein and in the claims, the terms“including” and “comprising” are used in an open-ended fashion, and thusshould be interpreted to mean “including, but not limited to . . . ”

It will be understood that the benefits and advantages described abovemay relate to one embodiment or may relate to several embodiments. Itwill further be understood that reference to “an” item refers to one ormore of those items.

The steps of the methods described herein may be carried out in anysuitable order, or simultaneously where appropriate.

Although the present invention and its advantages have been disclosed inthe context of certain illustrative, non-limiting embodiments, it shouldbe understood that various changes, substitutions, permutations, andalterations can be made without departing from the scope of theinvention as defined by the claims. It will be appreciated that anyfeature that is described in a connection to any one embodiment may alsobe applicable to any other embodiment.

What is claimed:
 1. An HVAC system for providing conditioned air to afirst closed space, wherein at least a portion of the system is disposedwithin a second closed space, the system comprising: an HVAC unitcomprising: a return air duct, a blower fluidly coupled to the returnair duct for pulling air through the return air duct, a conditioningcompartment fluidly coupled to the blower for receiving air therefrom tobe treated, wherein the conditioning compartment is formed with asampling port; an damper for selectively covering and uncovering thesampling port in response to a damper-control signal; a cooling unitfluidly coupled to the conditioning compartment for selectively coolingair therein, wherein the cooling unit comprises a flammable refrigerant,and a delivery duct fluidly coupled to the condition compartment fordischarging treated air from the conditioning compartment into the firstclosed space; a flammable-component detector disposed within the secondclosed space and positioned proximate the HVAC unit such that anyflammable refrigerant within the conditioned compartment would flowthrough the sampling port when the damper is open and onto theflammable-component detector, wherein the flammable-component detectoris operable to produce a detection signal; and a processing unitcomprising at least one processor and at least one memory, theprocessing unit communicatively coupled to the flammable-componentdetector for receiving the detection signal therefrom and coupled to thedamper for selectively providing the damper-control signal.
 2. Thesystem of claim 1, wherein the processing unit is furthercommunicatively coupled to the blower to receive an operational-statussignal from the blower, and wherein the at least one processor and atleast one memory are configured to perform the following steps: receivethe operational-status signal from the blower; open the damper when theoperational-status signal from the blower indicates that the blower isnot operating; and close the damper when the operational-status signalfrom the blower indicates that the blower is operating.
 3. The system ofclaim 1, wherein the processing unit is further communicatively coupledto the blower to receive an operational-status signal from the blower,and wherein the at least one processor and at least one memory areconfigured to perform the following steps: receive an operational-statussignal from the blower; open the damper when the operational-statussignal from the blower indicates that the blower is not operating; closethe damper when the operational-status signal from the blower indicatesthat the blower is operating; monitor the detection signal from theflammable-component detector; and send an alert when the detectionsignal is indicative of a flammable component at least equal to an alertthreshold.
 4. The system of claim 3, further comprising: a displaydisposed within the first closed space, wherein the display iscommunicatively coupled to the processing unit; and wherein display isoperable to receive the alert from the processing unit and provide asensory alert.
 5. The system of claim 3, further comprising: a displaydisposed within the first closed space, wherein the display iscommunicatively coupled to the processing unit; wherein display isoperable to receive the alert from the processing unit and provide asensory alert, wherein the sensor alert is a visual alert.
 6. The systemof claim 3, further comprising: a display disposed within the firstclosed space, wherein the display is communicatively coupled to theprocessing unit; wherein display is operable to receive the alert fromthe processing unit and provide a sensory alert, wherein the sensoralert is an audible alert.
 7. The system of claim 1, wherein theprocessing unit is further communicatively coupled to the blower toreceive an operational-status signal from the blower and to provideblower-control signal thereto, and wherein the at least one processorand at least one memory are configured to perform the following steps:receive an operational-status signal from the blower; open the damperwhen the operational-status signal from the blower indicates that theblower is not operating; close the damper when the operational-statussignal from the blower indicates that the blower is operating; monitorthe detection signal from the flammable-component detector; send analert when the detection signal is indicative a flammable component atleast equal to an alert threshold; and send the blower-control signal toactive the blower in response a detection signal indicative of aflammable component at least equal to the alert threshold.
 8. The systemof claim 1, further comprising a ventilation blower disposed within thesecond closed space and communicatively coupled to the processing unitfor receiving a ventilation-activation signal and wherein the processingunit is further communicatively coupled to the blower to receive anoperational-status signal from the blower and to provide blower-controlsignal thereto, and wherein the at least one processor and at least onememory are configured to perform the following steps: receive anoperational-status signal from the blower; open the damper when theoperational-status signal from the blower indicates that the blower isnot operating; close the damper when the operational-status signal fromthe blower indicates that the blower is operating; monitor the detectionsignal from the flammable-component detector; send an alert when thedetection signal is indicative a flammable component at least equal toan alert threshold; and send the blower-control signal to activate theblower in response a detection signal indicative of a flammablecomponent at least equal to the alert threshold and send theventilation-activation signal to the ventilation blower.
 9. The systemof claim 1, further comprising a cooling subsystem, the coolingsubsystem comprising: a closed-conduit pathway, wherein the flammablerefrigerant is disposed within the closed conduit pathway; a compressorfluidly coupled to the closed-conduit pathway for compressing therefrigerant; a condenser fluidly coupled to the closed-conduit pathwaydownstream for the compressor for cooling the refrigerant; an expansiondevice coupled to the closed-conduit pathway downstream of the condenserfor decreasing a pressure of the refrigerant; and the cooling unithaving a heat-exchange surface and fluidly coupled to the closed-conduitpathway for receiving the flammable refrigerant.
 10. The system of claim1, wherein the HVAC unit further comprises a heating device fluidlycoupled to the conditioning compartment for selectively heating airtherein.
 11. The system of claim 10, wherein the heating device is afurnace.
 12. The system of claim 10, wherein the heating device is anelectrical heating element.
 13. An HVAC system for providing conditionedair to a first closed space, wherein at least a portion of the system isdisposed within a second closed space, the system comprising: an HVACunit comprising: a return air duct, a blower fluidly coupled to thereturn air duct for pulling air through the return air duct, aconditioning compartment fluidly coupled to the blower for receiving airtherefrom to be treated, a cooling unit fluidly coupled to theconditioning compartment for selectively cooling air therein, whereinthe cooling unit comprises a flammable refrigerant, and a delivery ductfluidly coupled to the condition compartment for discharging treated airfrom the conditioning compartment into the first closed space; aflammable-component detector, wherein the flammable-component detectoris operable to produce a detection signal; a first probe fluidly coupledto the flammable-component detector and to the conditioning compartment;a second probe fluidly coupled to the flammable-component detector andto the second closed space; a selector for selectively providing fluidflow in the first probe and for selectively providing fluid flow in thesecond probe; and a processing unit comprising at least one processorand at least one memory, the processing unit communicatively coupled tothe flammable-component detector for receiving a detection signaltherefrom, and wherein the at least one processor and at least onememory is operable to perform the following steps: monitor the detectionsignal, and send an alert when the detection signal is indicative aflammable component at least equal to an alert threshold.
 14. The systemof claim 13, wherein the selector is a plurality of control valves. 15.The system of claim 13, wherein the selector is a plurality of sampleblowers, wherein a first sample blower of the plurality of sampleblowers is associated with the first probe and a second sample blower ofthe plurality of sample blowers is associated with the second probe. 16.The system of claim 13, wherein the alert threshold is one-half of abase threshold for a flammable-component detector having only a singleprobe.
 17. The system of claim 13, further comprising a third probefluidly coupled to the flammable-component detector and to a thirdclosed space, and wherein the alert threshold is one-third of a basethreshold for a flammable-component detector having only a single probe.18. The system of claim 13, wherein the HVAC unit further comprises aheating device fluidly coupled to the conditioning compartment forselectively heating air therein.
 19. An HVAC system for providingconditioned air to a first closed space, wherein at least a portion ofthe system is disposed within a second closed space, the systemcomprising: a cooling unit comprising a flammable refrigerant; at leastone compartment wall separating the cooling unit from an equipmentspace, wherein the at least one compartment wall is formed with anaccess port therethrough; a controllable damper associated with theaccess port for selectively covering the access port; aflammable-component detector disposed within the equipment spaceproximate the access port through the at least one compartment wall; anda processing unit communicatively coupled to the damper for opening andclosing the damper.